Using Web of science, PubMed, and SPORTDiscus, we searched for studies published from 2000-01-02 to 2024-06-01. Keywords used included (Post-Traumatic Stress Disorder OR Post-Traumatic Neuroses) AND (exercise OR physical activity OR training OR fitness) AND (mechanism).

Only research and review literature published was included in this study. The topic of the included literature needed to be related to exercise and post-traumatic stress disorder or post-traumatic neuroses and physiologic mechanisms. Specifically, the review focuses on studies that: (1) address the exercise performance of individuals with PTSD, and (2) explicitly mention the physiological effects and mechanisms of exercise interventions for psychological disorder. In order to gain a more comprehensive understanding of the mechanisms of exercise interventions for PTSD, the subjects of exercise interventions were not limited. To further enhance the credibility and authority of the included literature, non-peer-reviewed articles, such as those from newspapers, news outlets, or conferences, were excluded. This decision ensures that the review incorporates only rigorously evaluated and methodologically robust studies. Non-peer-reviewed materials often lack academic rigor, detailed methodological descriptions, and transparency, reducing their reliability as references in academic reviews. For preventing subjectivity in literature screening, two researchers independently conducted the screening based on the criteria for inclusion and exclusion of literature (Figure 1).

After reviewing the articles, all authors reached a consensus to further screen the articles based on the following criteria: whether the studies were empirical, whether they employed exercise interventions, and whether they explained the physiological mechanisms underlying these interventions, among other considerations. The decision to include or exclude literature was made after agreement was reached. A total of 411 records were retrieved from the database. After removing duplicates, 221 records were reviewed for title, abstract, and article type to further exclude irrelevant literature. Most of the excluded literature was deemed irrelevant to the topic of this study. Relevant literature was manually identified by reviewing the references of selected papers. The full texts of the remaining literature were reviewed (Figure 2).

A narrative review is a scholarly summary along with interpretation and critique. Narrative reviews contribute to prospective perspectives, it is concerned mainly with producing generalisable “facts” to aid prediction (Wiersinga et al., 2020). Wiersinga et al. (2020), for example, published a narrative review, cited in JAMA network, citation 3,460, explaining the pathophysiology of coronavirus disease and suggesting strategies to reduce transmission (Greenhalgh et al., 2018). Although narrative studies are subjective to judgment in screening the literature, it enables a more comprehensive review of research on exercise interventions for PTSD to inspire other researchers to further develop empirical research. To minimize the potential risk of selection bias, a methodological approach consistent with the PRISMA entries of this study was used, employing 15 entries from the 27-item checklist. Entries that were not relevant to the narrative review were deleted. Our adherence was limited by the nature of narrative reviews, which differ from the systematic and meta-analytical scope of PRISMA, particularly in areas of synthesis of results, statistical analysis, and bias assessment (Figure 3).

The average quality score of the articles included in this review was 8.03 (±1.29). Of these, 10.06% had lower scores, 33.3% were of medium quality, and 56.1% were of high quality. According to the scoring criteria, the mean score fell within the high-quality range. This indicates that the overall quality of these studies was high and satisfactory in terms of study design and data support.

The mechanisms relevant to this review were identified by reading the literature and discussing among the co-authors. After a comprehensive assessment of the included literature by the co-authors, there were 72 documents with data extracted on topics relevant to this review. The included literature spans from 1996 to 2023 and covers various types of exercise interventions, including yoga, running, walking, and strength training. The populations studied in these interventions include veterans, adult females, adult males, and older adults.

Experimental findings indicate that PTSD is linked with structural and functional alterations in brain regions such as the amygdala, hippocampus, cingulate cortex, hypothalamus, dorsolateral prefrontal cortex, and ventral prefrontal cortex (Scott et al., 2015). These brain regions perform vital functions crucial to daily life, including emotional processing, working memory, behavioral inhibition, and cognitive flexibility (Woon et al., 2017). Upon a diagnosis of PTSD, individuals often experience dysfunctional executive functions, manifested by cognitive decline, working memory loss, and other impairments. Recently, exercise interventions have demonstrated positive effects on the central nervous system, offering the academic community a fresh perspective on PTSD interventions.

The autonomic nervous system (ANS) comprises sympathetic and parasympathetic nerves, with neuropeptide Y (NPY) serving as a sympathetic neurotransmitter primarily found in the periphery. NPY is involved in regulating stress responses in individuals. High activation of sympathetic nerves leads to the release of large amounts of NPY, resulting in increased blood pressure, inhibition of the vagus nerve, and the maintenance of energy balance. Studies have demonstrated decreased resting plasma NPY levels in veterans with PTSD, which diminishes their anxiolytic effects (Rämson et al., 2011; Scioli et al., 2020). To harness the function of NPY and alleviate PTSD symptoms, Rämson investigated the use of exercise training to enhance NPY function. Maximum-load exercise was identified as a potential mediator of PTSD symptom improvement in a study involving 90 veterans who underwent 3 months of progressive aerobic exercise. In addition, resistance training also has an effect on NPY release, enhancing NPY synthesis under stress conditions and increasing anxiolysis levels to ameliorate PTSD symptoms (Levine et al., 2014). Paradoxically, chronic stress-induced over-activation of the negative feedback regulation of NPY and the “exercise-NPY” production mechanism can lead to excessive NPY release into adipose tissue, resulting in obesity and metabolic syndrome (Levine et al., 2014). Thus, the challenge lies in enhancing anxiolysis levels while mitigating related comorbidities, a topic that warrants further investigation in subsequent studies.

Evidence suggests that resting parasympathetic nervous system (PNS) activity decreases and sympathetic nervous system (SNS) responses increase in PTSD patients under mental stress. Overactivation of the SNS during an individual’s encounter with psychological stress leads to abnormal bodily reactions, potentially resulting in diseases such as chronic heart failure, obesity, and hypertension. One potential mechanism influencing this process is a decrease in arterial baroreflex sensitivity (BRS) (Park et al., 2017). Arterial pressure receptors buffer arterial blood pressure fluctuations caused by physiological and psychological stress, playing a crucial role in immediate blood pressure control. Additionally, arterial pressure receptors can inhibit SNS activity, helping maintain blood pressure close to a set value. Studies have found that years of strength endurance training can markedly reduce heart rate, increase arterial pressure receptor sensitivity, and consequently assist individuals in regulating SNS abnormalities. Specifically, changes in parameters such as the Heather index, index of contractility (IC), acceleration index (ACI), and time to achieve maximal contractile strength of the left ventricle provide robust evidence of the increase in parasympathetic stimulation induced by exercise. Furthermore, spectral analysis showed that strength-endurance exercise led to a higher frequency of the heart rate variability (HRV) spectrum and a reduction in sympathetic nerve activity (Kowalik et al., 2019). Thus, arterial pressure receptor sensitivity is likewise one of the important targets for reducing cardiovascular complications in PTSD patients. In summary, exercise has the potential to regulate the autonomic nervous system, thereby alleviating PTSD symptoms. This regulatory effect also lays the foundation for understanding its broader influence on physiological systems, including the immune system (Kenney and Ganta, 2014).

Previous studies have demonstrated various interactions between the autonomic nervous system and the immune system, which underpin chronic inflammatory diseases, such as organ inflammation, pain, cardiovascular involvement, and fatigue (Bellocchi et al., 2022). PTSD is suggested to dysregulate the biological pathways of the autonomic nervous system (ANS) and the HPA axis, resulting in a pro-inflammatory state that triggers chronic low-grade inflammation (Neigh and Nali, 2016; Speer et al., 2018). During traumatic events in PTSD patients, cortisol levels decrease while immune system inflammation increases, resulting in a 2- to 3-fold rise in plasma concentrations of pro-inflammatory cytokines IL-1, IL-6, and TNF-α. This continuous elevation of inflammatory factors in the body, coupled with the failure of cortisol’s immune-suppressive and anti-inflammatory effects, contributes to chronic low-grade inflammation symptoms (Quinones et al., 2020; Pivac et al., 2023). Additionally, inflammation may predispose individuals to PTSD or even serve as the biological basis for triggering PTSD (Smid et al., 2015). Generally, both pro-inflammatory and anti-inflammatory cytokines are produced in response to in vitro stimuli, and their balance in the body determines the development of a pro- or anti-inflammatory environment. Therefore, both pro-inflammatory and anti-inflammatory cytokines may contribute to the development of PTSD symptoms. Pro-inflammatory factors directly adversely affect memory function and neuroplasticity. Severe psychological trauma stimulates several components of the immune system, with IL-1 playing a significant role, resulting in increased expression of pro-inflammatory cytokines in various brain regions such as the hippocampus, hypothalamus, and brainstem. Additionally, peripheral immune cells produce pro-inflammatory cytokines that affect various brain regions through humoral and neural pathways (Smid et al., 2015). Anti-inflammatory cytokines produced by exercise serve as a buffer against an overly pro-inflammatory environment. IL-6 mRNA is elevated during exercise through skeletal muscle contraction, which stimulates the release of the anti-inflammatory cytokines IL-10 and IL-1 receptor antagonist (IL-1ra), IL-10 does minimize inflammation-induced tissue damage, and IL-1ra inhibits the pro-inflammatory effects of TNF-a and IL-1β effects (Gopal et al., 2011; Fischer, 2006). This also stimulates the release of cortisol from the adrenal glands (which has an anti-inflammatory effect). IL-6 elevation due to exercise is evident in promoting an anti-inflammatory environment in the body by stimulating various cytokines. Trauma-induced reductions in the anti-inflammatory cytokine IFN-γ may also compromise cellular immunity. One study investigated the immune system of two groups of subjects after exposure to exam stress. It found that as stress increased, the serum IFN-γ level significantly decreased in the control group, while the difference in serum IFN-γ level between the yoga group and the pre-stress level was not statistically significant. It can be seen that yoga has a certain buffering effect on cellular immune damage.

PTSD is associated with cardiovascular disease (CVD) through complex mechanisms, with inflammation playing a key role in the pathogenesis of CVD. Inflammation is the immune system’s response to injury, aimed at removing pathogens from the infected area and promoting healing (Starkie et al., 2003). C-reactive protein (CRP) is an acute-phase protein and a biomarker of inflammation, regulated by IL-6 and other pro-inflammatory cytokines (Gleeson et al., 2011). Some studies have shown that the intrusive and avoidant symptoms of PTSD are significantly associated with CRP, indicating that PTSD may lead to immune system dysregulation (elevated CRP levels). Prolonged dysregulation can result in health risks such as obesity, cardiovascular disease, and other health problems (Alfaddagh et al., 2020).

A study of older adults compared the effects of aerobic exercise versus flexibility exercise on inflammation and mental illness. The intervention consisted of 45 min of aerobic exercise, three times a week for 10 months. Both types of exercise were found to improve depression and increase optimism. Aerobic exercise had the greatest effect on inflammation, with a significant reduction in CRP at the end of the intervention (Canetti et al., 2014). Additionally, lowering the respiratory rate can achieve a reduction in CRP and pro-inflammatory cytokines, thereby alleviating symptoms of hyperarousal (Kohut et al., 2006).

The central nervous system (CNS) and the sympathetic nervous system (SNS) interactively maintain the body’s adaptive physiological functions. The hypothalamic–pituitary–adrenal axis (HPA), the body’s major stress system, interacts with the SNS. The hypothalamus secretes corticotropin-releasing hormone (CRH), stimulating the pituitary gland to release adrenocorticotropic hormone (ACTH). ACTH stimulates the adrenal glands to release cortisol, which in turn acts on the hypothalamus and pituitary gland, providing negative feedback to regulate the system. According to the cross-stressor adaptation hypothesis, exercise training enhances the physiological stress response system’s adaptation, promoting cross-stressor tolerance. It even reduces sensitivity to non-exercise stressors (Kelly et al., 2018).

Studies have reported differences between the HPA axis in PTSD patients and the non-PTSD population, suggesting that risk factors for HPA axis dysregulation mainly include CRH overactivity and low cortisol levels (Sothmann and Facsmbuckworth, 1996). Excessive activation of CRH, a regulator of the HPA axis, amplifies the individual’s fear response. Li et al. found that long-term regular running exercise attenuates the response to exogenous CRH and raises basal cortisol levels, improving the functional state of the HPA axis. Related studies have also shown that 8 weeks of stretching and balancing exercises, combined with breathing and positive thinking training, can significantly increase basal serum cortisol concentrations, normalize cortisol levels, and improve PTSD symptoms (Dunlop and Wwong, 2019; Kim et al., 2013). Balasubramaniam et al. found that yoga interventions can modulate the HPA axis and increase BDNF, thereby reducing inflammation and lowering stress and anxiety (Balasubramaniam et al., 2012).